Compact Graphene-Based Spiking Neural Network With Unsupervised Learning Capabilities

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY IEEE Open Journal of Nanotechnology Pub Date : 2020-11-27 DOI:10.1109/OJNANO.2020.3041198
He Wang;Nicoleta Cucu Laurenciu;Yande Jiang;Sorin Dan Cotofana
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引用次数: 2

Abstract

To fully unleash the potential of graphene-based devices for neuromorphic computing, we propose a graphene synapse and a graphene neuron that form together a basic Spiking Neural Network (SNN) unit, which can potentially be utilized to implement complex SNNs. Specifically, the proposed synapse enables two fundamental synaptic functionalities, i.e., Spike-Timing-Dependent Plasticity (STDP) and Long-Term Plasticity, and both Long-Term Potentiation (LTP) and Long-Term Depression (LTD) can be emulated with the same structure by properly adjusting its bias. The proposed neuron captures the essential Leaky Integrate and Fire spiking neuron behavior with post firing refractory interval. We demonstrate the proper operation of the graphene SNN unit by relying on a mixed simulation approach that embeds the high accuracy of atomistic level simulation of graphene structures conductance within the SPICE framework. Subsequently, we analyze the way graphene synaptic plasticity affects the behavior of a 2-layer SNN example consisting of 6 neurons and demonstrate that LTP significantly increases the number of firing events while LTD is diminishing them, as expected. To assess the plausibility of the graphene SNN reaction to input stimuli we simulate its behavior by means of both SPICE and NEST, a well established SNN simulation framework, and demonstrate that the obtained reactions, characterized in terms of total number of firing events and mean Inter-Spike Interval (ISI) length, are in close agreement, which clearly suggests that the proposed design exhibits a proper behavior. Further, we prove the unsupervised learning capabilities of the proposed design by considering a 2-layer SNN consisting of 30 neurons meant to recognize the characters “A,” “E,” “I,” “O,” and “U,” represented with a 5 by 5 black and white pixel matrix. The SPICE simulation results indicate that the graphene SNN is able to perform unsupervised character recognition associated learning and that its recognition ability is robust to input character variations. Finally, we note that our proposal results in a small real-estate footprint (max. 30 nm$^2$ are required by one graphene-based device) and operates at 200 mV supply voltage, which suggest its suitability for the design of large-scale energy-efficient computing systems.
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具有无监督学习能力的紧凑石墨烯脉冲神经网络
为了充分释放基于石墨烯的神经形态计算设备的潜力,我们提出了一个石墨烯突触和一个石墨烯神经元,它们共同形成一个基本的峰值神经网络(SNN)单元,可以潜在地用于实现复杂的SNN。具体而言,该突触实现了两种基本的突触功能,即spike - time - dependent Plasticity (STDP)和Long-Term Plasticity,并且通过适当调整其偏倚,可以用相同的结构模拟Long-Term Potentiation (LTP)和Long-Term Depression (LTD)。该神经元捕获了基本的泄漏积分和放电后不应间隔的脉冲神经元行为。我们演示了石墨烯SNN单元的正确操作,依靠混合模拟方法,该方法在SPICE框架内嵌入了石墨烯结构电导率的高精度原子级模拟。随后,我们分析了石墨烯突触可塑性如何影响由6个神经元组成的2层SNN示例的行为,并证明LTP显着增加了放电事件的数量,而LTD则减少了它们,正如预期的那样。为了评估石墨烯SNN反应对输入刺激的合理性,我们通过SPICE和NEST(一个完善的SNN模拟框架)来模拟其行为,并证明所获得的反应,以发射事件总数和平均峰间间隔(ISI)长度为特征,非常一致,这清楚地表明所提出的设计表现出适当的行为。此外,我们通过考虑由30个神经元组成的2层SNN来识别字符“a”,“E”,“I”,“O”和“U”,用5 × 5的黑白像素矩阵表示,证明了所提出设计的无监督学习能力。SPICE仿真结果表明,石墨烯SNN能够进行无监督字符识别关联学习,并且其识别能力对输入字符变化具有鲁棒性。最后,我们注意到,我们的建议导致了一个小的房地产占用(最大。一个基于石墨烯的器件需要30 nm$^2$),并且在200 mV供电电压下工作,这表明它适合设计大规模节能计算系统。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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